Title :
Study of system instability in solar-array-based power systems
Author_Institution :
Electr. & Electron. Syst. Dept., Aerosp. Corp., El Segundo, CA, USA
fDate :
7/1/2000 12:00:00 AM
Abstract :
A study of power system stability, based on analytical modeling, is presented for application to a current-mode dc-dc converter power system with a solar array input and a line-filter interface. A fundamental analytical background is provided for use in analyses of systems of similar architecture. With this architecture, there is a potential for two sources of instability: (1) the relatively high-Q resonant tank formed by the input filter inductance (L) and the array capacitance (C) combined with excessive array voltage regulation loop-gain; and (2) positive feedback due to in-phase response produced by the current-mode converter at low frequencies. Such a low-frequency instability is dependent upon the magnitude of the array current, the array impedance, and the array voltage regulation loop-gain
Keywords :
DC-DC power convertors; current-mode circuits; feedback; power system stability; solar cell arrays; space vehicle power plants; voltage control; analytical background; analytical modeling; array capacitance; array impedance; array voltage regulation loop-gain; current-mode converter; current-mode dc-dc converter power system; high-Q resonant tank; in-phase response; input filter inductance; instability; line-filter interface; low-frequency instability; positive feedback; solar array input; solar-array-based power systems; spacecraft poser systems; stability; Analytical models; DC-DC power converters; Filters; Inductance; Power system analysis computing; Power system modeling; Power system stability; Power systems; Resonance; Voltage control;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
